SQL-based analytic algorithm for association

ABSTRACT

A method, apparatus, and article of manufacture for performing data mining applications in a relational database management system. An analytic algorithm for association is performed by the relational database management system to measure one or more associations between a plurality of items in a stream of transaction data stored in the relational database, wherein the analytic algorithm for association creates at least one analytic model within an analytic logical data model from data residing in the relational database.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims the benefit under 35 U.S.C. Section 119(e) of the commonly-assigned U.S. provisional patent application Serial No. 60/102,831, filed Oct. 2, 1998, by Timothy E. Miller, Brian D. Tate, James D. Hildreth, Miriam H. Herman, Todd M. Brye, and James E. Pricer, entitled Teradata Scalable Discovery, which application is incorporated by reference herein.

This application is also related to the following commonly-assigned utility patent applications:

application Ser. No. PCT/US99/22966, filed on same date herewith, by Timothy E. Miller, Brian D. Tate, James D. Hildreth, Todd M. Brye, Anthony L. Rollins, James E. Pricer, and Tej Anand, entitled SQL-Based Analyt Algorithms,

application Ser. No. 09/410,531, filed on same date herewith, by james D. Hiidreth, entitled SQL-Based Analytic Algorithm for Clustering,

application Ser. No. 09/410,530, filed on same date herewith, by Todd M. Brye, entitled SQL-Based Analytic Algorithm for Rule Induction,

application Ser. No. 09/411,818, filed on same date herewith, by Brian D. Tate, entitled SQL-Based Automated Histogram Bin Data Derivation Assist,

application Ser. No. 09/410,534, filed on same date herewith, by Brian D. Tate, entitled SQL-Based Automated, Adaptive, Histogram Bin Data Description Assist,

application Ser. No. PCT/US99/22995, filed on same date herewith, by Timothy E. Miller, Brian D. Tate, Miriam H. Herman, Todd M. Brye, and Anthony L. Rollins, entitled Data Mining Assists in a Relational Database Management System,

application Ser. No. 09/411,809, filed on same date herewith, by Todd M. Brye, Brian D. Tate, and Anthony L. Rollins, entitled SQL-Based Data Reduction Techniques for Delivering Data to Analytic Tools,

application Ser. No. PCT/US99/23031, filed on same date herewith, by Timothy E. Miller, Miriam H. Herman, and Anthony L. Rollins, entitled Techniques for Deploying Analytic Models in Parallel, and

application Ser. No. PCT/US99/23019, filed on same date herewith, by Timothy E. Miller, Brian D. Tate, and Anthony L. Rollins, entitled Analytic Logical Data Model, all of which are incorporated by reference herein.

BACKGROUND OF THE INVENTION

1. Field of the Invention

This invention relates in general to a relational database management system, and in particular, to an SQL-based analytic algorithm for association that creates analytic models from the data residing in a relational database.

2. Description of Related Art

Relational databases are the predominate form of database management systems used in computer systems. Relational database management systems are often used in so-called “data warehouse” applications where enormous amounts of data are stored and processed. In recent years, several trends have converged to create a new class of data warehousing applications known as data mining applications. Data mining is the process of identifying and interpreting patterns in databases, and can be generalized into three stages.

Stage one is the reporting stage, which analyzes the data to determine what happened. Generally, most data warehouse implementations start with a focused application in a specific functional area of the business. These applications usually focus on reporting historical snap shots of business information that was previously difficult or impossible to access. Examples include Sales Revenue Reporting, Production Reporting and Inventory Reporting to name a few. Stage two is the analyzing stage, which analyzes the data to determine why it happened. As stage one end-users gain previously unseen views of their business, they quickly seek to understand why certain events occurred; for example, a decline in sales revenue. After discovering a reported decline in sales, data warehouse users will then obviously ask, “Why did sales go down?” Learning the answer to this question typically involves probing the database through an iterative series of ad hoc or multidimensional queries until the root cause of the condition is discovered. Examples include Sales Analysis, Inventory Analysis or Production Analysis.

Stage three is the predicting stage, which tries to determine what will happen. As stage two users become more sophisticated, they begin to extend their analysis to include prediction of unknown events. For example, “Which end-users are likely to buy a particular product”, or “Who is at risk of leaving for the competition?” It is difficult for humans to see or interpret subtle relationships in data, hence as data warehouse users evolve to sophisticated predictive analysis they soon reach the limits of traditional query and reporting tools. Data mining helps end-users break through these limitations by leveraging intelligent software tools to shift some of the analysis burden from the human to the machine, enabling the discovery of relationships that were previously unknown.

Many data mining technologies are available, from single algorithm solutions to complete tool suites. Most of these technologies, however, are used in a desktop environment where little data is captured and maintained. Therefore, most data mining tools are used to analyze small data samples, which were gathered from various sources into proprietary data structures or flat files. On the other hand, organizations are beginning to amass very large databases and end-users are asking more complex questions requiring access to these large databases.

Unfortunately, most data mining technologies cannot be used with large volumes of data. Further, most analytical techniques used in data mining are algorithmic-based rather than data-driven, and as such, there are currently little synergy between data mining and data warehouses. Moreover, from a usability perspective, traditional data mining techniques are too complex for use by database administrators and application programmers, and are too difficult to change for a different industry or a different customer.

Thus, there is a need in the art for data mining applications that directly operate against data warehouses, and that allow non-statisticians to benefit from advanced mathematical techniques available in a relational environment.

SUMMARY OF THE INVENTION

To overcome the limitations in the prior art described above, and to overcome other limitations that will become apparent upon reading and understanding the present specification, the present invention discloses a method, apparatus, and article of manufacture for performing data mining applications in a relational database management system. An analytic algorithm for association is performed by the relational database management system to measure one or more associations between a plurality of items in a stream of transaction data stored in the relational database, wherein the analytic algorithm for association creates at least one analytic model within an analytic logical data model from data residing in the relational database.

An object of the present invention is to provide more efficient usage of parallel processor computer systems. An object of the present invention is to provide a foundation for data mining tool sets in relational database management systems. Further, an object of the present invention is to allow data mining of large databases.

BRIEF DESCRIPTION OF THE DRAWINGS

Referring now to the drawings in which like reference numbers represent corresponding parts throughout:

FIG. 1 is a block diagram that illustrates an exemplary computer hardware environment that could be used with the preferred embodiment of the present invention;

FIG. 2 is a block diagram that illustrates an exemplary logical architecture that could be used with the preferred embodiment of the present invention; and

FIGS. 3, 4 and 5 are flowcharts that illustrate exemplary logic performed according to the preferred embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

In the following description of the preferred embodiment, reference is made to the accompanying drawings, which form a part hereof, and in which is shown by way of illustration a specific embodiment in which the invention may be practiced. It is to be understood that other embodiments may be utilized and structural changes may be made without departing from the scope of the present invention.

OVERVIEW

The present invention provides a relational database management system (RDBMS) that supports data mining operations of relational databases. In essence, advanced analytic processing capabilities for data mining applications are placed where they belong, i.e., close to the data. Moreover, the results of these analytic processing capabilities can be made to persist within the database or can be exported from the database. These analytic processing capabilities and their results are exposed externally to the RDBMS by an application programmable interface (APD).

According to the preferred embodiment, the data mining process is an iterative approach referred to as a “Knowledge Discovery Analytic Process” (KDAP). There are six major tasks within the KDAP:

1. Understanding the business objective.

2. Understanding the source data available.

3. Selecting the data set and “pre-processing” the data.

4. Designing the analytic model.

5. Creating and testing the models.

6. Deploying the analytic models.

The present invention provides various components for addressing these tasks:

An RDBMS that executes Structured Query Language (SQL) statements against a relational database.

An analytic Application Programming Interface (API) that creates scalable data mining functions comprised of complex SQL statements.

Application programs that instantiate and parameterize the analytic API.

Analytic algorithms utilizing:

Extended ANSI SQL statements,

a Call Level Interface (CLI comprised of SQL staterments and programmatic iteration, and

a Data Reduction Utility Program comprised of SQL statements and programmatic iteration.

An analytical logical data model (LDM) that stores results from and information about the advanced analytic processing in the RDBMS.

A parallel deployer that controls parallel execution of the results of the analytic algorithms that are stored in the analytic logical data model.

The benefits of the present invention include:

Data mining of very large databases directly within a relational database.

Management of analytic results within a relational database.

A comprehensive set of analytic operations that operate within a relational database management system.

Application integration through an object-oriented API.

These components and benefits are described in more detail below.

HARDWARE ENVIRONMENT

FIG. 1 is a block diagram that illustrates an exemplary computer hardware environment that could be used with the preferred embodiment of the present invention. In the exemplary computer hardware environment, a massively parallel processing (MPP) computer system 100 is comprised of one or more processors or nodes 102 interconnected by a network 104. Each of the nodes 102 is comprised of one or more processors, random access memory (RAM), read-only memory (ROM), and other components. It is envisioned that attached to the nodes 102 may be one or more fixed and/or removable data storage units (DSUs) 106 and one or more data communications units DCUs) 108, as is well known in the art.

Each of the nodes 102 executes one or more computer programs, such as a Data Mining Application (APPL) 110 performing data mining operations, Advanced Analytic Processing Components (AAPC) 112 for providing advanced analytic processing capabilities for the data mining operations, and/or a Relational Database Management System (RDBMS) 114 for managing a relational database 116 stored on one or more of the DSUs 106 for use in the data mining applications, wherein various operations are performed in the APPL 110, AAPC 112, and/or RDBMS 114 in response to commands from one or more Clients 118. In alternative embodiments, the APPL 110 may be executed in one or more of the Clients 118, or on an application server on a different platform attached to the network 104.

Generally, the computer programs are tangibly embodied in and/or retrieved from RAM, ROM, one or more of the DSUs 106, and/or a remote device coupled to the computer system 100 via one or more of the DCUs 108. The computer programs comprise instructions which, when read and executed by a node 102, causes the node 102 to perform the steps necessary to execute the steps or elements of the present invention.

Those skilled in the art will recognize that the exemplary environment illustrated in FIG. 1 is not intended to limit the present invention. Indeed, those skilled in the art will recognize that other alternative hardware environments may be used without departing from the scope of the present invention. In addition, it should be understood that the present invention may also apply to other computer programs than those disclosed herein.

LOGICAL ARCHITECTURE

FIG. 2 is a block diagram that illustrates an exemplary logical architecture of the AAPC 112, and its interaction with the APPL 110, RDBMS 114, relational database 116, and Client 118, according to the preferred embodiment of the present invention. In the preferred embodiment, the AAPC 112 includes the following components:

An Analytic Logical Data Model (LDM) 200 that stores results from the advanced analytic processing in the RDBMS 114,

One or more Scalable Data Mining Functions 202 that comprise complex, optimized SQL statements that perform advanced analytic processing in the RDBMS 114,

An Analytic Application Programming Interface (API) 204 that provides a mechanism for an APPL 110 or other component to invoke the Scalable Data Mining Functions 202,

One or more Analytic Algorithms 206 that can operate as standalone applications or can be invoked by another component, wherein the Analytic Algorithms 206 comprise:

Extended ANSI SQL 208 that can be used to implement a certain class of Analytic Algorithms 206,

A Call Level Interface (CLI) 210 that can be used when a combination of SQL and programmatic iteration is required to implement a certain class of Analytic Algorithms 206, and

A Data Reduction Utility Program 212 that can be used to implement a certain class of Analytic Algorithms 206 where data is first reduced using SQL followed by programmatic iteration.

An Analytic Algorithm Application Programming Interface (API) 214 that provides a mechanism for an APPL 110 or other components to invoke the Analytic Algorithms 206,

A Parallel Deployer 216 that controls parallel executions of the results of an Analytic Algorithm 206 (sometimes referred to as an analytic model) that are stored in the Analytic LDM 200, wherein the results of executing the Parallel Deployer 216 are stored in the RDBMS 114.

Note that the use of these various components is optional, and thus only some of the components may be used in any particular configuration.

The preferred embodiment is oriented towards a multi-tier logical architecture, in which a Client 118 interacts with the various components described above, which, in turn, interface to the RDBMS 114 to utilize a large central repository of enterprise data stored in the relational database 116 for analytic processing.

In one example, a Client 118 interacts with an APPL 110, which interfaces to the Analytic API 204 to invoke one or more of the Scalable Data Mining Functions 202, which are executed by the RDBMS 114. The results from the execution of the Scalable Data Mining Functions 202 would be stored as an analytic model within an Analytic LDM 200 in the RDBMS 114.

In another example, a Client 118 interacts with one or more Analytic Algorithms 206 either directly or via the Analytic Algorithm API 214. The Analytic Algorithms 206 comprise SQL statements that may or may not include programmatic iteration, and the SQL statements are executed by the RDBMS 114. In addition, the Analytic Algorithms 206 may or may not interface to the Analytic API 204 to invoke one or more of the Scalable Data Mining Functions 202, which are executed by the RDBMS 114. Regardless, the results from the execution of the Analytic Algorithms 206 would be stored as an analytic model within an Analytic LDM 200 in the RDBMS 114.

In yet another example, a Client 118 interacts with the Parallel Deployer 216, which invokes parallel instances of the results of the Analytic Algorithms 206, sometimes referred to as an Analytic Model. The Analytic Model is stored in the Analytic LDM 200 as a result of executing an instance of the Analytic Algorithms 206. The results of executing the Parallel Deployer 216 are stored in the RDBMS 114.

In still another example, a Client 118 interacts with the APPL 110, which invokes one or more Analytic Algorithms 206 either directly or via the Analytic Algorithm API 214. The results would be stored as an analytic model within an Analytic LDM 200 in the RDBMS 114.

The overall goal is to significantly improve the performance, efficiency, and scalability of data mining operations by performing compute and/or I/O intensive operations in the various components. The preferred embodiment achieves this not only through the parallelism provided by the MPP computer system 100, but also from reducing the amount of data that flows between the APPL 110, AAPC 112, RDBMS 114, Client 118, and other components.

Those skilled in the art will recognize that the exemplary configurations illustrated and discussed in conjunction with FIG. 2 are not intended to limit the present invention. Indeed, those skilled in the art will recognize that other alternative configurations may be used without departing from the scope of the present invention. In addition, it should be understood that the present invention may also apply to other components than those disclosed herein.

Scalable Data Mining Functions

The Scalable Data Mining Functions 202 comprise complex, optimized SQL statements that are created, in the preferred embodiment, by parameterizing and instantiating the corresponding Analytic APIs 204. The Scalable Data Mining Functions 202 perform much of the advanced analytic processing for data mining applications, when performed by the RDBMS 114, without having to move data from the relational database 116.

The Scalable Data Mining Functions 202 can be categorized by the following functions:

Data Description: The ability to understand and describe the available data using statistical techniques. For example, the generation of descriptive statistics, frequencies and/or histogram bins.

Data Derivation: The ability to generate new variables (transformations) based upon existing detailed data when designing an analytic model. For example, the generation of predictive variables such as bitmaps, ranges, codes and mathematical functions.

Data Reduction: The ability to reduce the number of variables (columns) or observations (rows) used when designing an analytic model. For example, creating Covariance, Correlation, or Sum of Squares and Cross-Products (SSCP) Matrices.

Data Reorganization: The ability to join or denormalize pre-processed results into a wide analytic data set.

Data Sampling/Partitioning: The ability to intelligently request different data samples or data partitions. For example, hash data partitioning or data sampling.

The principal theme of the Scalable Data Mining Functions 202 is to facilitate analytic operations within the RDBMS 114, which process data collections stored in the database 116 and produce results that also are stored in the database 116. Since data mining operations tend to be iterative and exploratory, the database 116 in the preferred embodiment comprises a combined storage and work space environment. As such, a sequence of data mining operations is viewed as a set of steps that start with some collection of tables in the database 116, generate a series of intermediate work tables, and finally produce a result table or view.

Analytic Algorithms

The Analytic Algorithms 206 provide statistical and “machine learning” methods to create analytic models within the Analytic LDM 200 from the data residing in the relational database 116. Analytic Algorithms 206 that are completely data driven, such as association, can be implemented solely in Extended ANSI SQL 208. Analytic Algorithms 206 that require a combination of SQL and programmatic iteration, such as induction, can be implemented using the CLI 210. Finally, Analytic Algorithms 206 that require almost complete programmatic iteration, such as clustering, can be implemented using a Data Reduction Utility Program 212. This approach involves data pre-processing that reduces the amount of data that a non-SQL algorithm can then process.

The Analytic Algorithms 206 significantly improve the performance and efficiency of data mining operations by providing the technology components to perform advanced analytic operations directly against the RDBMS 114. In addition, the Analytic Algorithms 206 leverage the parallelism that exists in the MPP computer system 100, the RDBMS 114, and the database 116.

The Analytic Algorithms 206 provide data analysts with an unprecedented option to train and apply “machine learning” analytics against massive amounts of data in the relational database 116. Prior techniques have failed as their sequential design is not optimal in an RDBMS 114 environment. Because the Analytic Algorithms 206 are implemented in Extended ANSI SQL 208, through the CLI 210, and/or by means of the Data Reduction Utility Program 212, they can therefore leverage the scalability available on the MPP computer system 100. In addition, taking a data-driven approach to analysis, through the use of complete Extended ANSI SQL 208, allows people other than highly educated statisticians to leverage the advanced analytic techniques offered by the Analytic Algorithms 206.

Analytic Algorithm for Association

As mentioned above, Analytic Algorithms 206 that are completely data driven can be implemented solely in Extended ANSI SQL 208. An example of an Analytic Algorithm 206 is association, also known as affinity analysis.

Business problems requiring association or affinity analysis have traditionally been implemented in a desktop environment and outside of the database environment. With data volumes growing to unprecedented proportions, there are several key problems with this sequential approach to affinity analysis, including:

Analyses run too slow with samples of large volumes of data.

Prior art implementations are unable to use massively parallel processing MPP) technology for scalability.

The algorithm itself may be too complex for use by database administrators and application programmers.

The algorithm is too difficult to change for a different industry or a different customer.

Analyses are algorithmic-based rather than data-driven, resulting in little to no synergies between data mining and data warehouse applications.

The Analytic Algorithm 206 for association of the present invention provides a scalable technology component that supports the design, creation, testing and deployment of affinity models. Thus, the Analytic Algorithm 206 for association provides data analysts with an unprecedented option to analyze massive amounts of data. In addition, the preferred embodiment takes a data driven approach to the analysis that allows people other than highly educated statisticians to leverage the advanced analytic techniques offered by the algorithm. As a result, all the analytic processing associated with association can be done using all of the data, without having to move the data outside the RDBMS 114 environment.

In the preferred embodiment, the Analytic Algorithm 206 for association operates against a set of tables in the relational database 116 that are populated with transaction-level data, the source of which could be point-of-sale devices, automated teller machines, call centers, the Internet, etc. The Analytic Algorithm 206 for association is comprised of SQL statements that are used to process this data, wherein the SQL statements typically build relationships between and among data elements in the tables. For example, the SQL statements used to process data from point-of-sale devices may build relationships between and among products and pairs of products. Additionally, the dimension of time can be added in such a way that these relationships can be analyzed to determine how they change over time, which is known as a sequence analysis. As the implementation of the preferred embodiment is solely in SQL statements, the design takes advantage of the hardware and software environment of the preferred embodiment by decomposing the SQL statements into a plurality of sort and merge steps that can be executed concurrently in parallel by the MPP computer system 100.

Operation of the Analytic Algorithm for Association

The Analytic Algorithm 206 for association measures one or more associations between a plurality of items in a stream of transaction data. Associations are relationships between one or more items in a transaction or “item group”, sometimes called the “antecedent” or “left-hand-side”, and one or more different items in the same item group, sometimes called the “consequent” or “right-hand-side”. For example, the association of items A and B taken as A implies B (A→B) within item groups in the data can be thought of as a measure of the likelihood that B occurs in a particular item group given that A occurs in the same item group. There can be one or more items on the left side of an association, and one or more items on the right side.

Three measures are provided for each discovered association A→B, which are defined as follows:

Support: The percentage of item groups that contain an item or set of items. As such, a support value should always be >0 and <=1.

Confidence: The likelihood of an item (A) occurring in an item group given that different item (B) is in the item group. More specifically, this is the support of A,B divided by the support of A.

Lift: A measure of how much the likelihood of an item (B) occurring in an item group is increased by the presence of a different item (A) in the item group. It is calculated by dividing the confidence of A→B by the support of B.

In the preferred embodiment, the Analytic Algorithm 206 for association is implemented as a script that is comprised of a number of different SQL statements. To begin with, transaction-level data from a customer's data warehouse is extracted into a base table which contains two columns: a GROUP identifier and an ITEM identifier. This data is retrieved from one or more transaction tables and its source will depend on the nature of the business problem to be solved and on the associations to be determined. It should be noted that a great deal of creativity can be applied to and customer value derived from defining what is an “item group” and an “item”.

Examples in Retail, Financial and Communications include the following:

Retail: A retailer may define an item group as all the items purchased by one customer at a check-out stand, and an item as anything from an individual item to a class of items such as dairy or produce.

Financial: A banker on the other hand, might define an item group as all of the transactions performed by a customer in a given time period, and an item as the combined value of channel and transaction code (such as ATM-DEPOSIT).

Communications: A telephone company might define an item group as all the phone calls made by a customer in a given time period, and an item as the combined value of call plan and call type (such as international calls under Call Plan One).

After creating and loading this base table, the script creates and loads a temporary table with a single value that comprises the count of the number of unique item groups or transactions. This value is used repeatedly in the calculations that follow.

The next steps in the script build the support tables for one, two, or more items. Each of these support tables is built by joining the base table with itself and performing the necessary aggregation, constraint, and grouping functions. The item groups containing various combinations of items are counted and this is divided by the total number of item groups, thereby providing the support for the combinations. A performance gain is obtained by operating directly against the base table rather than building intermediate tables of combinations of items and joining these intermediate tables.

The first support table to be built is the single item support table containing an ITEM identifier and SUPPORT value for each item in the base table that contains a support value below a minimum specified support value of interest (for example, 0.5). A second table (base₂) is then built from the base table by selecting only those values that have a certain pre-defined minimum level of support. Next, the support tables for two or more items are built in preparation for analyzing combinations of items adding up to two or more, respectively.

For example, when considering four items, the combinations include 1→1, 2→1, 2→2, or 3→1, determined as follows:

1→1: Determine all possible pairs of items in base₂, regardless of ordering, so that the first item can be considered as the left-hand side and the second item can be considered as the right-hand side of all possible associations. For example, if the pair A,B occurs in the table for the A→B association, then the pair B,A must also occur to consider the B→A association.

2→1: Determine all three-way combinations of items, but taken in such a way that the first two items must always be considered together and do not include inverses. For example, if (A,B),C occurs, then (B,A),C will not occur. The results determine all 2→1 and 1→2 associations, in addition to isolating 3-item sets in determining 3→1 and 1→3 associations.

2→2: Determine all four-way combinations of items, but taken in such a way that the first two items must always be considered together and do not include inverses, with the same applying to the last two items in a combination. For example, if (A,B),(C,D) occurs, then (B,A),P,C) does not occur. The results determine all 2→2 associations.

3→1: Determine all four-way combinations of items, but taken in such a way that the first three items must always be considered together and do not include other orderings. For example, if (A,B,C),D occurs, then (B,A,C),D and (C,A,B),D do not occur. The results determine all 3→1 and 1→3 associations.

This pattern continues, although business value seems to diminish after four items are considered.

Additional associations of the form N→M, are determined as follows. First, a support table is created for N+M items, grouping together the first N items and the next M items. This is done by joining the base₂ table with itself N+M times, along with the count of the number of unique item groups or transactions. WHERE clause phrases of the form “TX.ITEM_ID<TX+1.ITEM_ID” are used to group together the items. For example, if N=3 and M=2, then “T1.ITEM_ID<T2.ITEM_ID”, “T2.ITEM_ID<T3.ITEM_ID”, and “T4.ITEM_ID<T5.ITEM_ID” are used. Further, items in the first group of N items are checked to be unequal to items in a second group of N items. Of course, the group ids must all be equal.

Finally, support, confidence and lift are calculated by joining the support tables described previously. A separate table is built for each combination case, i.e., when considering four items, the combinations include 1→1, 1→2, 2→1, 2→2, 1→3, or 3→1. The general form of these joins is to join: (1) the support table matching up the left-hand side of the association, (2) the support table matching up the entire association, and (3) the support table matching the right-hand side of the association.

For associations of the form N→M, support, confidence and lift are determined by joining N_support, N→M_support, and M_support tables together. This means that the method must also have support tables for N items and for M items in addition to the support table for N+M items described above. Note that a (N−1)→1 table can be used for N_support and a M→N table for M→N support.

Analytic Logical Data Model

The Analytic LDM 200, which is integrated with the relational database 116 and the RDBMS 114, provides logical entity and attribute definitions for advanced analytic processing, i.e., the Scalable Data Mining Functions 202 and Analytic Algorithms 206, performed by the RDBMS 114 directly against the relational database 116. These logical entity and attribute definitions comprise metadata that define the characteristics of data stored in the relational database 116, as well as metadata that determines how the RDBMS 114 performs the advanced analytic processing. The Analytic LDM 200 also stores processing results from this advanced analytic processing, which includes both result tables and derived data for the Scalable Data Mining Functions 202, Analytic Algorithms 206, and the Parallel Deployer 216. The Analytic LDM 200 is a dynamic model, since the logical entities and attributes definitions change depending upon parameterization of the advanced analytic processing, and since the Analytic LDM 200 is updated with the results of the advanced analytic processing.

Logic of the Preferred Embodiment

Flowcharts which illustrate the logic of the preferred embodiment of the present invention are provided in FIGS. 3, 4 and 5. Those skilled in the art will recognize that this logic is provided for illustrative purposes only and that different logic may be used to accomplish the same results.

Referring to FIG. 3, this flowchart illustrates the logic of the Scalable Data Mining Functions 202 according to the preferred embodiment of the present invention.

Block 300 represents the one or more of the Scalable Data Mining Functions 202 being created via the API 204. This may entail, for example, the instantiation of an object providing the desired function.

Block 302 represents certain parameters being passed to the API 204, in order to control the operation of the Scalable Data Mining Functions 202.

Block 304 represents the metadata in the Analytic LDM 200 being accessed, if necessary for the operation of the Scalable Data Mining Function 202.

Block 306 represents the API 204 generating a Scalable Data Mining Function 204 in the form of a data mining query based on the passed parameters and optional metadata.

Block 308 represents the Scalable Data Mining Function 204 being passed to the RDBMS 114 for execution.

Referring to FIG. 4, this flowchart illustrates the logic of the Analytic Algorithms 206 according to the preferred embodiment of the present invention.

Block 400 represents the Analytic Algorithms 206 being invoked, either directly or via the Analytic Algorithm API 214.

Block 402 represents certain parameters being passed to the Analytic Algorithms 206, in order to control their operation.

Block 404 represents the metadata in the Analytic LDM 200 being accessed, if necessary for the operation of the Analytic Algorithms 206.

Block 406 represents the Analytic Algorithms 206 passing SQL statements to the RDBMS 114 for execution and Block 408 optionally represents the Analytic Algorithms 206 performing programmatic iteration. Those skilled in the art will recognize that the sequence of these steps may differ from those described above, in that the sequence may not include both steps, it may include additional steps, and it may include iterations of these steps.

In the preferred embodiment, the Analytic Algorithm 206 for association is performed entirely by SQL statements passed to the RDBMS 114 for execution at Block 406 and no programmatic iteration is required at Block 408. Generally, these SQL statements perform the following steps:

extracting transaction-level data from the relational database 116 (or other database) into a base table in the relational database 116 that contains two columns: a GROUP identifier and an ITEM identifier.

creating and loading a temporary table in the relational database 116 with a single value comprising a count of the number of unique item groups or transactions.

building support tables for one, two, or more items, wherein each of these support tables is built by joining the base table with itself and performing the necessary aggregation, constraints and grouping functions.

calculating support, confidence and lift by joining the support tables described previously. The general form of these joins is to join: (1) the support table matching up the left-hand side of the association, (2) the support table matching up the entire association, and (3) the support table matching the right-hand side of the association. A separate table is built for each combination case.

Block 410 represents the Analytic Algorithms 206 storing results in the Analytic LDM 200.

Referring to FIG. 5, this flowchart illustrates the logic performed by the RDBMS 114 according to the preferred embodiment of the present invention.

Block 500 represents the RDBMS 114 receiving a query or other SQL statements.

Block 502 represents the RDBMS 114 analyzing the query.

Block 504 represents the RDBMS 114 generating a plan that enables the RDBMS 114 to retrieve the correct information from the relational database 116 to satisfy the query.

Block 506 represents the RDBMS 114 compiling the plan into object code for more efficient execution by the RDBMS 114, although it could be interpreted rather than compiled.

Block 508 represents the RDBMS 114 initiating execution of the plan.

Block 510 represents the RDBMS 114 generating results from the execution of the plan.

Block 512 represents the RDBMS 114 either storing the results in the Analytic LDM 200, or returning the results to the Analytic Algorithm 206, APPL 110, and/or Client 118.

CONCLUSION

This concludes the description of the preferred embodiment of the invention. The following describes an alternative embodiment for accomplishing the same invention. Specifically, in an alternative embodiment, any type of computer, such as a mainframe, minicomputer, or personal computer, could be used to implement the present invention.

In summary, the present invention discloses a method, apparatus, and article of manufacture for performing data mining applications in a relational database management system. An analytic algorithm for association is performed by the relational database management system to measure one or more associations between a plurality of items in a stream of transaction data stored in the relational database, wherein the analytic algorithm for association creates at least one analytic model within an analytic logical data model from data residing in the relational database.

The foregoing description of the preferred embodiment of the invention has been presented for the purposes of illustration and description. It is not intended to be exhaustive or to limit the invention to the precise form disclosed. Many modifications and variations are possible in light of the above teaching. It is intended that the scope of the invention be limited not by this detailed description, but rather by the claims appended hereto. 

What is claimed is:
 1. A system for performing data mining applications, comprising: (a) a computer system having one or more data storage devices connected thereto; (b) a relational database management system, executed by the computer system, for managing a relational database stored on the data storage devices and (c) an analytic algorithm for association, performed by the relational database management system, for measuring one or more associations between a plurality of items in a stream of transaction data stored in the relational database, wherein the analytic algorithm for association creates at least one analytic model within an analytic logical data model from data residing in the relational database, and wherein the analytic algorithm for association extracts the transaction data into a base table in the relational database, builds one or more support tables for one or more of the items by joining the base table with itself and performing aggregation, constraint, and grouping functions thereon, and calculates support, confidence and lift by joining the support tables.
 2. The system of claim 1, wherein the computer system is a massively parallel processing (MPP) computer system, and the analytic algorithm for association is decomposed into a plurality of steps that are executed concurrently in parallel by the massively processing computer system.
 3. The system of claim 1, wherein the analytic algorithm for association further comprises an affinity analysis.
 4. The system of claim 1, wherein the associations are relationships between one or more first items in an item group and one or more second items in the item group.
 5. The system of claim 4, wherein the analytic algorithm for association further comprises means for analyzing the relationships to determine how they change over time.
 6. The system of claim 1, wherein the analytic algorithm for association further comprises: means for creating a temporary table in the relational database with a single value comprising a count of unique item groups in the base table.
 7. The system of claim 1, wherein the base table contains at least a group identifier column and an item identifier column.
 8. The system of claim 6, further comprising means for counting the item groups in the base table containing various combinations of items and for dividing the counted item groups by the count of unique item groups in the temporary table to obtain a support for each of the combinations.
 9. The system of claim 1, wherein a first support table is a single item support table containing at least an item identifier and a support value for each item in the base table which contains a support value below a minimum specified support value of interest.
 10. The system of claim 1, wherein a second support table is built from the base table by selecting only those values that have a certain pre-defined minimum level of support.
 11. The system of claim 1, wherein the support tables for two or more items are built in preparation for analyzing combinations of two or more items.
 12. The system of claim 4, wherein the support tables are joined using one or more joins selected from a group comprising: (1) joining the support table matching the first item of the association, (2) joining the support table matching both first and second items of the association, and (3) joining the support table matching the second item of the association.
 13. A method for performing data mining applications, comprising: (a) managing a relational database stored on one or more data storage devices connected to a computer; and (b) performing an analytic algorithm for association in the relational database management system to measure one or more associations between a plurality of items in a stream of transaction data stored in the relational database, wherein the analytic algorithm for association creates at least one analytic model within an analytic logical data model from data residing in the relational database, and wherein the analytic algorithm for association extracts the transaction data into a base table in the relational database, builds one or more support tables for one or more of the items by joining the base table with itself and performing aggregation, constraint, and grouping functions thereon, and calculates support, confidence and lift by joining the support tables.
 14. The method of claim 13, wherein the computer is a massively parallel processing (MPP) computer system, and the analytic algorithm for association is decomposed into a plurality of steps that are executed concurrently in parallel by the massively processing computer system.
 15. The method of claim 13, wherein the analytic algorithm for association farther comprises an affinity analysis.
 16. The method of claim 13, wherein the associations are relationships between one or more first items in an item group and one or more second items in the item group.
 17. The method of claim 16, wherein the analytic algorithm for association further comprises analyzing the relationships to determine how they change over time.
 18. The method of claim 16, wherein the support tables are joined using one or more joins selected from a group comprising: (1) joining the support table matching the first item of the association, (2) joining the support table matching both first and second items of the association, and (3) joining the support table matching the second item of the association.
 19. The method of claim 13, wherein the analytic algorithm for association further comprises creating a temporary table in the relational database with a single value comprising a count of unique item groups in the base table.
 20. The method of claim 19, further comprising counting the item groups in the base table containing various combinations of items and for dividing the counted item groups by the count of unique item groups in the temporary table to obtain a support for each of the combinations.
 21. The method of claim 13, wherein the base table contains at least a group identifier column and an item identifier column.
 22. The method of claim 13, wherein a first support table is a single item support table containing at least an item identifier and a support value for each item in the base table which contains a support value below a minimum specified support value of interest.
 23. The method of claim 13, wherein a second support table is built from the base table by selecting only those values that have a certain pre-defined minimum level of support.
 24. The method of claim 13, wherein the support tables for two or more items are built in preparation for analyzing combinations of two or more items.
 25. An article of manufacture comprising logic embodying a method for performing data mining applications, comprising: (a) managing a relational database stored on one or more data storage devices connected to a computer; and (b) performing an analytic algorithm for association in the relational database management system to measure one or more associations between a plurality of items in a stream of transaction data stored in the relational database, therein the analytic algorithm for association creates at least one analytic model with an analytic logical data model from data residing in the relational database, and wherein the analytic algorithm for association extracts the transaction data into a base cable in the relational database, builds one or more support tables for one or more of the items by joining the base table with itself and performing aggregation, constraint, and grouping functions thereon, and calculates support, confidence and lift by joining the support tables.
 26. The article of manufacture of claim 25, wherein the computer is a massively parallel processing (MPP) computer system, and the analytic algorithm for association is decomposed into a plurality of steps that are executed concurrently in parallel by the massively processing computer system.
 27. The article of manufacture of claim 25, wherein the analytic algorithm for association further comprises an affinity analysis.
 28. The article of manufacture of claim 25, wherein the associations are relationships between one or more first items in an item group and one or more second items in the item group.
 29. The article of manufacture of claim 28, wherein the analytic algorithm for association comprises analyzing the relationships to determine how they change over time.
 30. The article of manufacture of claim 28, wherein the support tables are joined using one or more joins selected from a group comprising: (1) joining the support table matching the first item of the association, (2) joining the support table matching both first and second items of the association, and (3) joining the support table matching the second item of the association.
 31. The article of manufacture of claim 25, wherein the analytic algorithm for association further comprises creating a temporary table in the relational database with a single value comprising a count of unique item groups in the base table.
 32. The article of manufacture of claim 31, further comprising counting the item groups in the base table containing various combinations of items and for dividing the counted item groups by the count of unique item groups in the temporary table to obtain a support for each of the combinations.
 33. The article of manufacture of claim 25, wherein the base table contains at least a group identifier column and an item identifier column.
 34. The article of manufacture of claim 25, wherein a first support table is a single item support table containing at least an item identifier and a support value for each item in the base table which contains a support value below a minimum specified support value of interest.
 35. The article of manufacture of claim 25, wherein a second support table is built from the base table by selecting only those values that have a certain pre-defined minimum level of support.
 36. The article of manufacture of claim 25, wherein the support tables for two or more items are built in preparation for analyzing combinations of two or more items. 